World Library  
Flag as Inappropriate
Email this Article

Valve gear

Article Id: WHEBN0000591379
Reproduction Date:

Title: Valve gear  
Author: World Heritage Encyclopedia
Language: English
Subject: Gresley conjugated valve gear, Corliss steam engine, Steam engine, Stephenson valve gear, Bulleid chain-driven valve gear
Collection: Locomotive Parts, Locomotive Valve Gear, Steam Engines
Publisher: World Heritage Encyclopedia

Valve gear

The valve gear of a steam engine is the mechanism that operates the inlet and exhaust valves to admit steam into the cylinder and allow exhaust steam to escape, respectively, at the correct points in the cycle. It can also serve as a reversing gear. It is sometimes referred to as the "motion".


  • Purpose 1
  • Valve gear designs 2
    • Reciprocating valve gears 2.1
      • Early types 2.1.1
      • Link gears 2.1.2
        • Constant lead gear (Walschaerts-type gear)
        • Dual eccentric gear (Stephenson-type gears)
      • Lever and link gear (Baker-type) 2.1.3
      • Radial gears 2.1.4
    • Poppet valve gears 2.2
    • Conjugating gears 2.3
    • Bulleid chain-driven valve gear 2.4
    • Corliss valve gear 2.5
  • Power reverse 3
  • See also 4
  • References 5
  • External links 6


In the simple case, this can be a relatively simple task as in the internal combustion engine in which the valves always open and close at the same points. This is not the ideal arrangement for a steam engine, though, because greatest power is achieved by keeping the inlet valve open throughout the power stroke (thus having full boiler pressure, minus transmission losses, against the piston throughout the stroke) while peak efficiency is achieved by only having the inlet valve open for a short time and then letting the steam expand in the cylinder (expansive working).

The point at which steam stops being admitted to the cylinder is known as the cutoff and the optimal position for this varies depending on the work being done and the tradeoff desired between power and efficiency. Steam engines are fitted with regulators (throttles in US parlance) to vary the restriction on steam flow, but controlling the power via the cutoff setting is generally preferable since it makes for more efficient use of boiler steam.

A further benefit may be obtained by admitting the steam to the cylinder slightly before front or back dead centre. This advanced admission (also known as lead steam) assists in cushioning the inertia of the motion at high speed.

In the internal combustion engine, this task is performed by cams on a camshaft driving poppet valves, but this arrangement is not commonly used with steam engines, partly because achieving variable engine timing using cams is complicated. Instead, a system of eccentrics, cranks and levers is generally used to control a D slide valve or piston valve from the motion. Generally, two simple harmonic motions with different fixed phase angles are added in varying proportions to provide an output motion that is variable in phase and amplitude. A variety of such mechanisms have been devised over the years, with varying success.

Both slide and piston valves have the limitation that intake and exhaust events are fixed in relation to each other and cannot be independently optimised. Lap is provided on steam edges of the valve, so that although the valve stroke reduces as cutoff is advanced, the valve is always fully opened to exhaust. However, as cutoff is shortened, the exhaust events also advance. The exhaust release point occurs earlier in the power stroke and compression earlier in the exhaust stroke. Early release wastes some energy in the steam, and early closure also wastes energy in compressing an otherwise unnecessarily large quantity of steam. Another effect of early cutoff is that the valve is moving quite slowly at the cutoff point, and this causes 'wire drawing' of the steam, another wasteful thermodynamic effect visible on an indicator diagram.

These inefficiencies drove the widespread experimentation in poppet valve gears for locomotives. Intake and exhaust poppet valves could be moved and controlled independently of each other, allowing for better control of the cycle. In the end, not a great number of locomotives were fitted with poppet valves, but they were common in steam cars and lorries, for example virtually all Sentinel lorries, locomotives and railcars used poppet valves. A very late British design, the SR Leader class, used sleeve valves adapted from internal combustion engines, but this class was not a success.

In stationary steam engines, traction engines and marine engine practice, the shortcomings of valves and valve gears were among the factors that lead to compound expansion. In stationary engines trip valves were also extensively used.

Valve gear designs

Valve gear was a fertile field of invention, with probably several hundred variations devised over the years. However, only a small number of these saw any widespread use. They can be divided into those that drove the standard reciprocating valves (whether piston valves or slide valves), those used with poppet valves, and stationary engine trip gears used with semi-rotary Corliss valves or drop valves.[1]

Reciprocating valve gears

Early types

  • Slip-eccentric - This gear is now confined to model steam engines, and low power hobby applications such as steam launch engines, ranging to a few horsepower. The eccentric is loose on the crankshaft but there are stops to limit its rotation relative to the crankshaft. Setting the eccentric to the forward running and reverse running positions can be accomplished manually by rotating the eccentric on a stopped engine, or for many engines by simply turning the engine in the desired rotation direction, where the eccentric then positions itself automatically. The engine is pushed forwards to put the eccentric in the forward gear position and backwards to put it in the backward gear position. There is no variable control of cutoff.[2] On the London and North Western Railway, some of the three-cylinder compounds designed by Francis William Webb from 1889 used a slip eccentric to operate the valve of the single low-pressure cylinder. These included the Teutonic, Greater Britain and John Hick classes.[3]
  • Gab or hook gear - used on earliest locomotives. Allowed reversing but no control of cutoff.

Link gears

Constant lead gear (Walschaerts-type gear)

One component of the motion comes from a crank or eccentric. The other component comes from a separate source, usually the crosshead.

  • Deeley valve gear - fitted to several express locomotives on the Midland Railway. The combination levers were driven, as normal, from the crossheads. Each expansion link was driven from the crosshead on the opposite side of the engine.
  • Young valve gear - used the piston rod motion on one side of the locomotive to drive the valve gear on the other side. Similar to the Deeley gear, but with detail differences.
  • Baguley valve gear - used by W.G. Bagnall.
  • Bagnall-Price valve gear - a variation of Walschaerts used by W.G. Bagnall. This gear is fitted to Bagnall 3023 and 3050, both preserved on the Welsh Highland Railway.
  • James Thompson Marshall seems to have designed at least two different modifications of Walschaerts gear.
    • One was relatively conventional.
    • The other was very complex and drove separate valves on top of the cylinder (for admission) and underneath the cylinder (for exhaust). After the inventor's death, this gear was fitted experimentally to Southern Railway N Class locomotive number 1850, the work taking from 16 October 1933 to 3 February 1934; but it failed on 22 March 1934. Since the inventor was unable to modify the design, the valve gear was replaced by standard Walschaerts gear between 24 March and 11 April 1934.[4]
  • Isaacson's patent valve gear - a modified Walschaerts gear, patented in 1907 by Rupert John Isaacson, and others, patent no. GB190727899, published 13 August 1908.[5] It was fitted to the Garstang and Knot-End Railway's 2-6-0T Blackpool (built 1909) and to Midland Railway No. 382 during 1910-11.[6] Isaacson also has a patent (GB126203, published 8 May 1919) for an improved sight-feed lubricator. This was patented jointly with his representative, Ysabel Hart Cox.[7]
  • Kingan-Ripken valve gear. This is a Walschaerts-type gear in which the combination lever is linked to an arm on the connecting rod, near its small end, instead of to the crosshead. Patented in Canada by James B. Kingan and Hugo F. Ripken, patent CA 204805, issued 12 October 1920.[8] This gear was fitted to some locomotives of the Minneapolis, St. Paul and Sault Ste. Marie Railroad.[9]
Dual eccentric gear (Stephenson-type gears)
Stephenson's Valve gear. Two eccentrics at nearly 180 degree phase difference work cranks from the main drive shaft. Either can be selected to work the valve slide by shifting the slotted expansion link.

Two eccentrics joined by a curved or straight link. A simple arrangement which works well at low speed. At high speed, a Walschaerts-type gear is said to give better steam distribution and higher efficiency.

Lever and link gear (Baker-type)

Baker valve gear assembly

Radial gears

Both components of the motion come from a single crank or eccentric. A problem with this arrangement (when applied to locomotives) is that one of the components of the motion is affected by the rise and fall of the locomotive on its springs. This probably explains why radial gears were largely superseded by Walschaerts-type gears in railway practice but continued to be used in traction and marine engines.

Poppet valve gears

Conjugating gears

View of Henschel & Son conjugated valve gear mechanism used on Victorian Railways H class locomotive, driven from the outside Walschaerts valve gear

These enable a 3-cylinder or 4-cylinder locomotive to be built with only two sets of valve gear. The best known is Gresley conjugated valve gear, used on 3-cylinder locomotives. Walschaerts gear is usually used for the two outside cylinders. Two levers connected to the outside cylinder valve rods drive the valve for the inside cylinder. Harold Holcroft devised a different method for conjugating valve gear by linking the middle cylinder to the combination lever assembly of an outside cylinder, creating the Holcroft valve gear derivative. On a 4-cylinder locomotive the arrangement is simpler. The valve gear may be inside or outside and only short rocking-shafts are needed to link the valves on the inside and outside cylinders.

Bulleid chain-driven valve gear

See Bulleid chain-driven valve gear

Corliss valve gear

Large stationary engines often used an advanced form of valve gear developed by George Henry Corliss, usually called Corliss valve gear. This gear used separate valves for inlet and exhaust so that the inlet cut-off could be controlled precisely. This resulted in much improved efficiency.

Power reverse

Some larger steam engines employ a power reverse, which is a servo mechanism, usually powered by steam. This makes control of the valve gear easier for the driver.

See also


  1. ^ Steam Locomotive Valve Gear Animations of Stephenson's, Walschaerts', Baker's, Southern and Young's valve gear., Accessed 1 September 2014
  2. ^ "Slip-eccentric valve gear". Retrieved 2012-12-02. 
  3. ^ van Riemsdijk, John T. (1994). Compound Locomotives: An International Survey. Penryn: Atlantic Books. pp. 23–24.  
  4. ^ Bradley, D.L. (April 1980) [1961]. The Locomotive History of the South Eastern & Chatham Railway (2nd ed.). London:  
  5. ^ "Espacenet - Bibliographic data". Retrieved 2013-01-12. 
  6. ^ "Brief Biographies of Mechanical Engineers". Retrieved 2013-01-12. 
  7. ^ "Espacenet - Bibliographic data". Retrieved 2013-01-12. 
  8. ^ "CIPO - Patent - 204805". 1920-10-12. Retrieved 2013-01-13. 
  9. ^
  10. ^ 0-6-4st Badger
  11. ^

External links

  • Berry accelerator valve gear.
  • Diagrams of Walschaerts valve gear and Stephenson valve gear, as supplied on working steam model locomotives.
  • [2] Animations of 5 Stephenson, Walschaert, Baker, Southern, and Young valve gears.
This article was sourced from Creative Commons Attribution-ShareAlike License; additional terms may apply. World Heritage Encyclopedia content is assembled from numerous content providers, Open Access Publishing, and in compliance with The Fair Access to Science and Technology Research Act (FASTR), Wikimedia Foundation, Inc., Public Library of Science, The Encyclopedia of Life, Open Book Publishers (OBP), PubMed, U.S. National Library of Medicine, National Center for Biotechnology Information, U.S. National Library of Medicine, National Institutes of Health (NIH), U.S. Department of Health & Human Services, and, which sources content from all federal, state, local, tribal, and territorial government publication portals (.gov, .mil, .edu). Funding for and content contributors is made possible from the U.S. Congress, E-Government Act of 2002.
Crowd sourced content that is contributed to World Heritage Encyclopedia is peer reviewed and edited by our editorial staff to ensure quality scholarly research articles.
By using this site, you agree to the Terms of Use and Privacy Policy. World Heritage Encyclopedia™ is a registered trademark of the World Public Library Association, a non-profit organization.

Copyright © World Library Foundation. All rights reserved. eBooks from Project Gutenberg are sponsored by the World Library Foundation,
a 501c(4) Member's Support Non-Profit Organization, and is NOT affiliated with any governmental agency or department.